Grounded antenna for a wireless communication device and method

ABSTRACT

A wireless communication device includes an antenna for wireless communication with a remote interrogator. Several embodiments are disclosed to increase the options available to designers of wireless communication devices. In some embodiments, the antenna is a quarter wavelength long with one end of the antenna being grounded to provide desired impedance matching characteristics. The position of the ground plane relative to the antenna is also varied between embodiments. The connection from a wireless communication chip to the antenna is also varied between embodiments to provide alternate structures.

RELATED APPLICATIONS

This application is a continuation of 10/131,575, filed on Apr. 24, 2002 U.S. Pat. No. 7,098,850.

This application is a continuation-in-part of patent application entitled “Wireless Communication Device and Method”, Ser. No. 09/678,271, filed on Oct. 3, 2000 U.S. Pat. No. 6,501,435, which is a continuation-in-part of application Ser. No. 09/618,505, filed on Jul. 18, 2000 U.S. Pat. No. 6,483,473, the disclosures of which are hereby incorporated by reference in their entireties as if set forth fully herein.

FIELD OF THE INVENTION

The present invention relates to an apparatus, system and methods of providing a wireless communication device and communicating information concerning an item containing the wireless communication device.

BACKGROUND OF THE INVENTION

It is often desired to track and identify items, such as packages, containers, etc., and to communicate information concerning such items wirelessly. One method of tracking and providing information concerning packages is to attach a wireless communication device, such as a radio frequency identification (RFID) transponder or other identification device, to packages. The information communicated concerning the packages may include expiration dates, “born on” dates, lot numbers, manufacturing information, and the like. A wireless communication device may be attached to an individual package or to a container containing multiple packages.

A problem exists when a wireless communication device is attached to packaging or containers constructed out of a conductive material such as foil. A pole antenna connected to the wireless communication device will not radiate properly if the wireless communication device is attached on the outside of the package. The pole antenna will be shielded if the wireless communication device is placed inside the package.

It may be advantageous for such a wireless communication device to communicate on different frequencies so that one device can be used for various applications. For instance, an operating frequency of 2.45 GHz is used frequently outside the United States, but an operating frequency of 915 MHz is frequently used in the United States. Many companies manufacture wireless communication devices that are capable of operating at both 915 MHz and 2.45 GHz frequencies so that either frequency can be chosen for operation. However, wireless communications device applications, such as attaching wireless communication devices to packages for informative and tracking purposes, configure the device to communicate on only one frequency—either a frequency for the United States or a frequency for use abroad. It would be advantageous to construct a wireless communication device with an antenna structure that is capable of communicating at more than one frequency. This would allow one wireless communication device to be applicable for uses in both the United States and abroad.

In addition to conductive materials, wireless communication devices are also used with many other substrates. Each substrate has its own dielectric characteristics, which typically affect the impedance matching between the wireless communication device and its antenna. Impedance matching ensures the most efficient energy transfer between an antenna and the wireless communication device.

Further, there are occasions when it may be desirable to change the impedance of the antenna to achieve better impedance matching between the antenna and the wireless communication electronics. While many techniques are known, other techniques, such as those in the present invention, are not and have not been applied to a wireless communication device. Thus, there is a need to provide a variety of techniques to achieve the desired impedance matching so that there are more opportunities available to a designer, such as choice of geometry, size, or the like, to achieve the desired operating frequency without compromising the performance of the wireless communication device.

SUMMARY OF THE INVENTION

The present invention relates to a wireless communication device comprising an antenna, a wireless communication chip, and a substrate. In particular, the present invention provides a number of alternate antenna structures that have varied impedances from the previously suggested antenna structures to effectuate proper impedance matching between the wireless communication chip and the antenna.

In a first embodiment, the antenna is a linear conductor to which the wireless communication chip is coupled at a point removed from the center of the antenna. The chip and one end of the antenna element are shorted to a ground plane. The other end of the antenna element is an open circuit.

In a second embodiment, the wireless communication chip is positioned on a second conductive strip that is shorted to the ground plane at one end. The second conductive strip is capacitively coupled to an antenna element, and the antenna element is additionally shorted to the other side of the ground plane from the second conductive strip.

In a third embodiment, a Co-Planar Waveguide Ground plane (CPWG) is used with the wireless communication chip. The CPWG is located on the same side of the substrate as the wireless communication chip. The wireless communication chip is coupled to the CPWG section that in turns acts as a radiating element.

In a fourth embodiment, an inter digital capacitive structure is used to vary the relative capacitive cross coupling between the elements as needed. Specifically, a tab extends from the wireless communication device and proximate to the antenna element. The antenna element is spaced from the tab, but capacitively couples to the tab on a plurality of sides.

In a fifth embodiment, the tabs or coupling strips act as an antenna for a second operating frequency in conjunction with a CPWG antenna or other radiating element. This may be done with an inter digital capacitive structure or by other coupling as needed or desired. In particular, the tabs or coupling strips form a dipole antenna operating at a first frequency and the CPWG antenna or other antenna element operates at a second frequency.

In all of these embodiments, it is possible that the antenna is not electrically shorted per se, but rather has a very low impedance reactive or resistive connection between the ground plane and one end of the antenna.

Further, methods of constructing these embodiments are provided. In particular, a substrate of a desired size is prepared. Two conductive strips are prepared. The first conductive strip is cut to act as a ground plane and the antenna element. The second conductive strip comprises the tabs and the wireless communication chip. The two conductive strips may comprise an adhesive layer and are wrapped around the substrate in order to form the wireless communication device.

It should be appreciated that the parent applications discussed wireless communication devices associated with a package, container or other material to communicate information concerning the package, container or other material. A wireless communication device is provided that contains a control system, communication electronics, memory, and an antenna. The wireless communication device may contain a sensor to sense environmental conditions surrounding the wireless communication device. The wireless communication device contains one or more tabs constructed out of conductive material. The tab(s) may serve as both a pole antenna and may attach the wireless communication device to a slot, thereby forming a slot antenna. While helpful in some embodiments such is not required in all the embodiments herein presented.

In one embodiment, the wireless communication device is a transponder that is interrogated by an interrogation reader for communication purposes. The wireless communication device is attached to a package that may be constructed out of a conductive material, such as foil packaging used for food or liquid.

The tab(s) attach to the surface of the package. In one embodiment, the tab(s) are attached to the surface of a package. In a different embodiment, the tab(s) are reactively coupled to the surface of the package through a dielectric material. The dielectric material can be an adhesive material placed on the tab(s) to attach the wireless communication device to a package.

In another embodiment, the tab(s) form a pole antenna to communicate in a first mode at one frequency, and the tab(s) are attached across a slot in a package to communicate in a second mode at a second frequency. One tab is used in one embodiment to form a monopole type antenna, and two tabs are used in another embodiment to form a dipole antenna. In another embodiment, the tab(s) can be varied in shape and size to adjust to surfaces that vary in form.

An asymmetrical antenna arrangement may be provided so that the impedance of the antenna is not substantially affected by the substrate to which the wireless communication device is attached. In one embodiment, the asymmetrical antenna arrangement is an asymmetrical dipole antenna formed by asymmetrical tabs. For example, the wireless communication device may be placed in an indentation in the substrate so that the wireless communication device does not protrude from the substrate surface. Asymmetrical tabs are placed on the surface of the substrate. The asymmetrical tabs are connected to the wireless communication device with feed lines to provide an asymmetrical dipole antenna. In a second embodiment, the asymmetrical antenna arrangement is an asymmetrical slot antenna.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram illustrating communication between a wireless communication device and an interrogation reader;

FIG. 2 is an illustration of the wireless communication device with slot antenna on a foil food package;

FIG. 3A is a schematic top view diagram of the wireless communication device with coupling tab devices containing a dielectric, adhesive material;

FIG. 3B is a schematic side view diagram of the wireless communication device in FIG. 3A;

FIG. 3C is a schematic diagram of the wireless communication device having its own slot;

FIG. 4 is a schematic diagram of the wireless communication device attached across a slot to form a slot antenna;

FIG. 5A is a schematic diagram of the wireless communication device having a slot antenna of a particular width to match the impedance between the wireless communication device and the slot;

FIG. 5B is a schematic diagram of the wireless communication device illustrated in FIG. 5A with a slot of different width;

FIG. 6 is a schematic diagram of a circularly polarized slot antenna;

FIG. 7 is a schematic diagram of another type of packaging containing a wireless communication device;

FIG. 8A is a schematic diagram of the wireless communication device having a slot antenna formed by a foil package closing;

FIG. 8B is a schematic diagram of the wireless communication device illustrated in FIG. 8A with the foil package having an additional seal below the wireless communication device;

FIG. 9 is a flowchart illustrating the operation of the wireless communication device when sensing to detect its presence outside of a package;

FIG. 10 is a schematic diagram of wireless communication devices mounted on a carrier or support for stamping into packages in an assembly line;

FIG. 11A is a top plan view of a wireless communication device with an asymmetrical antenna arrangement;

FIG. 11B is a side elevational view of the wireless communication device of FIG. 11A;

FIG. 12A is a schematic diagram of a particular asymmetrical antenna arrangement;

FIG. 12B is a schematic diagram of the matched gain of the particular asymmetrical antenna arrangement in FIG. 12A;

FIG. 12C is a schematic diagram of the matched gain of the particular asymmetrical antenna arrangement in FIG. 12A with lossless FR4;

FIG. 13 is a schematic diagram of an alternative asymmetrical antenna arrangement;

FIG. 14A is a schematic diagram of another alternative asymmetrical antenna arrangement;

FIG. 14B is a schematic diagram of a second embodiment of the alternative asymmetrical antenna arrangement of FIG. 14A;

FIG. 15A is a schematic diagram of a wireless communication device having an asymmetrical antenna arrangement on a side of an aluminum beverage can;

FIG. 15B is a schematic diagram of wireless communication device having an asymmetrical antenna arrangement on the bottom dome of an aluminum beverage can;

FIG. 16 is a schematic diagram of a wireless communication device mounting arrangement;

FIG. 17 is a schematic diagram of a wireless communication device using an asymmetrical slot antenna;

FIG. 18 illustrates a first embodiment of a quarter wavelength resonator with a grounded radiator;

FIG. 19 illustrates a second embodiment of a quarter wavelength resonator with a grounded radiator;

FIG. 20 illustrates a third embodiment of a quarter wavelength resonator with a grounded radiator using a Co Planar Waveguide Ground plane;

FIG. 21 illustrates an alternate coupling technique for use with the quarter wavelength resonators;

FIG. 22 illustrates a second alternate coupling technique for use with the quarter wavelength resonators;

FIG. 23 illustrates a multifrequency antenna arrangement for use with the wireless communication device;

FIG. 24 illustrates an alternate multifrequency antenna arrangement for use with the wireless communication device;

FIG. 25 illustrates a kit to assemble a quarter wavelength antenna according to one embodiment of the present invention;

FIG. 26 illustrates a first step in assembling the kit of FIG. 25;

FIG. 27 illustrates a second step in assembling the kit of FIG. 25; and

FIG. 28 illustrates an assembled quarter wavelength antenna arrangement as assembled from the kit of FIG. 25.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention is directed to several new antenna arrangements on wireless communication devices. However, this technology builds on a line of patent applications with related subject matter. This related subject matter is presented in full below, with the new material described with reference to FIGS. 18–28 following.

The prior inventions were directed to a device, system and method of attaching a wireless communication device, such as a radio frequency identification device (RFID), to a package or container to communicate information about the package or container. The package may be an individual package containing specific contents, or an individual, exterior package containing a group of additional, interior individual packages. The word “package” and “container” are used interchangeably herein to describe a material that houses contents, such as goods or other individual packages, and equivalent structures. The present invention should not be limited to any particular meaning or method when either “package” or “container” is used.

As illustrated in FIG. 1, the invention includes a wireless communication device 10 for electronic communication. Some wireless communication devices 10 have both a transmitter and receiver. Other wireless communication devices 10, known in the art as “transponders,” are interrogated by interrogation reader 50, whereby the transponder communicates back by altering field 58 containing interrogation signal 56. This description refers to the terms “transponder” and wireless communication device 10 interchangeably, and the use of the term transponder is not intended to limit the type of wireless communication device 10 applicable to the present invention. Wireless communication devices 10 are available that communicate at various frequencies, including UHF and VHF. One embodiment of the present invention uses a wireless communication device 10, also called a “transponder,” that is a passive radio-frequency device with the ability to rectify incoming radio energy and provide power to power the device for communication and operation. The invention is also applicable to active devices that have their own power source for communications. It should be readily understood to one of ordinary skill in the art that there are many other different types of wireless communication devices 10 that allow electronic communication and thus the present invention is not limited to any one particular type.

Transponder 10 includes a control system 12 and communication electronics 14. Transponder 10 may also contain memory 18 for storage of information to be communicated to an interrogation reader 50. Alternatively, transponder 10 may store information such as an identification number or other information by using diodes, dip switches or some other like circuitry in lieu of erasable memory 18. Antenna 16 is provided to receive the interrogation signal 56 from interrogation reader 50. Antenna 16 may be either external to or internal to transponder 10. The particular type and location of antenna 16 will depend on the operating frequency of transponder 10 and the particular design desired. Transponder 10 may also be connected to sensor 20 for sensing ambient or environmental information surrounding transponder 10, package 200 containing transponder 10, or the contents of package 200. One example of sensor 20 may be a quartz crystal resonator like that described in U.S. Pat. No. 5,922,550, entitled “Biosensing devices which produce diffraction images,” incorporated herein by reference its entirety. A quartz crystal resonator detects analytes that may be present in food. Analytes include, but are not limited to, microorganisms such as bacteria, yeasts, fungi and viruses.

Antenna 16 receives signal 56 through the radiated interrogation field 58. Antenna 16 passes received signals 56 to communication electronics 14. Communication electronics 14 contain circuitry necessary to interpret signal 56 from field 58 and to further communicate the interpreted signal to control system 12. Control system 12 is an integrated circuit, printed circuit board, or other type of microprocessor or micro-controller electronics that controls the operations of the transponder 10. Control system 12 is connected to communication electronics 14 to communicate and receive transmissions. Control system 12 is also connected to memory 18 for storing and retrieving information. Control system 12 may further include a clock (not shown). Control system 12 determines if any actions are needed in response to the communications received from communication electronics 14.

FIG. 1 also depicts how communication is achieved with transponder 10 using an interrogation reader 50. Interrogation reader 50 contains interrogation communication electronics 52 and an interrogation antenna 54. Interrogation reader 50 communicates with the transponder 10 by emitting an electronic signal 56 modulated in a frequency by interrogation communication electronics 52 through interrogation antenna 54. Interrogation antenna 54 may be any type of antenna that can radiate signal 56 through a field 58 so that a compatible device, such as transponder 10, can receive such signal 56 through its own antenna 16. Field 58 could be electro-magnetic, magnetic, or electric. Signal 56 is a message containing information or a specific request for the transponder 10.

When antenna 16 is in the presence of field 58 emitted by interrogation reader 50, communication electronics 14 are energized by signal 56, thereby energizing transponder 10. Transponder 10 remains energized so long as antenna 16 is in the field 58 of interrogation reader 50. Communication electronics 14 demodulates signal 56 and sends the message containing information or request to control system 12 for appropriate actions. For example, the request may be for transponder 10 to communicate its identification, or information about a material or package containing transponder 10, such as date of manufacture, place of manufacture, and/or lot number. The message may also be a request for information regarding ambient or environmental measurements sensed by sensor 20.

Another description of a transponder 10 that may be used with the present invention is located in U.S. Pat. No. 5,347,280, entitled “Frequency diversity transponder arrangement,” incorporated herein by reference in its entirety. Transponder 10 is one type of wireless communication device. Other types of wireless communication devices 10 may be used with the present invention. For instance, transponder 10 may have a transmitter that can send information to interrogation reader 50 without having to alter signal 56. Transponder 10 may contain a battery to power the transmitter, or an energy storage unit that is charged by energy received from signal 56 when wireless communication device 10 is in the range of field 58. It is readily understood to one of ordinary skill in the art that there are many other types of wireless communications devices and communication techniques than those described herein, and the present invention is not limited to a particular type of device, technique or method.

Transponder 10 may be attached on any type of device or package to identify and communicate information concerning the device or package. For instance, transponder 10 can be attached to a food package and may contain identification information and other information about the food contained inside the package, such as its date of manufacture, “born on” date, expiration date for sale or consumption and lot number. For example, transponder 10 can be attached to a wine bottle and contain information concerning the type of wine and its ingredients or make up, the date of manufacture, and expiration dates, if applicable. Transponder 10 can be attached to virtually any device or package conceivable.

FIG. 2 illustrates transponder 10 attached to a food package 200. Antenna 16 can either be a slot antenna 16A, as illustrated in FIG. 2, or a pole antenna 16B, as illustrated in FIGS. 3A and 3B. A slot 300 is provided in package 200 to provide a slot antenna 16A. Package 200 includes a surface 202. At least one tab, made out of conductive material, such as a metallic material, is attached to transponder 10, and more particularly to communication electronics 14 inside transponder 10. Two or more tabs 100 may also be attached to transponder 10 to provide antenna 16. The use of “tab” is used in singular and plural herein, and reference in either form is not intended to limit the invention to only one tab 100, or more than one tab 100.

Tabs 100 are attached to slot 300 to form a slot antenna 16A. For the purposes of this specification, the word “attached” is used generically to mean either attached directly or connected to slot 300. The tabs 100 may either be attached on slot 300 or proximate to slot 300. Tabs 100 may also serve as pole antenna 16B. Tabs 100 may also be constructed by applying a conductive fluid (e.g. conductive ink) onto surface 202.

The present invention can also be used with transponder 10 containing one tab 100 to form either slot antenna 16A or pole antenna 16B. One tab 100 can be used to form pole antenna 16B in the form of an antenna having monopole-like radiation pattern. If one tab 100 is used to form slot antenna 16B, tab 100 is attached to slot 300, and transponder 10 is attached, in the form of grounding, to slot 300 to form a ground plane. Using one tab 100 as a slot antenna 16B will create a monopole-like radiation pattern.

If surface 202 is constructed out of a conductive material, it may be advantageous to use tabs 100 to create a slot antenna 16A rather than a pole antenna 16B. Examples of conductive surfaces 202 include food foil packaging, wine bottles cork foil, jewelry, watches, cigar label foil, and alcoholic bottle foil labels. If tabs 100 are attached on a conductive surface 202 without forming a slot antenna 16A, the radiation pattern of the resulting pole antenna 16B created by tabs 100 may not be properly tuned to the operating frequency of transponder 10. Factors such as the conductivity and surface area of surface 202 affect the radiation pattern of a pole antenna 16B formed by tabs 100 when tabs 100 are attached to surface 202. Packages 200 vary greatly in size, shape, and area. It is desirable for transponder 10 and tabs 100 to be manufactured such that transponder 10 operates at a desired frequency when using tabs 100 as a pole antenna 16B, regardless of the particular characteristics of package 200.

Packages 200 that are constructed out of conductive material, such as foil, containing transponder 10 inside the package 200 cannot use a pole antenna 16B. The radiation pattern of pole antenna 16B is shielded by the conductive material. Therefore, another reason for using tabs 100 to create a slot antenna 16A rather than a pole antenna 16B may be so that packages constructed out of conductive material and containing transponder 10 inside package 200 can effectively communicate desired information wirelessly.

If tabs 100 are attached on surface 202 that is not conductive, tabs 100 can function at the desired operating frequency as a pole antenna 16B, regardless of the characteristics of package 200. If two tabs 100 are used, the tabs 100 serve as a dipole antenna 16B. One tab 100, instead of two tabs 100, may also be used to serve as antenna 16, creating a monopole type radiation pattern as previously described above. A ground plane may be provided between transponder 10 and surface 202 such that communication electronics 12 is attached to surface 202 to from a ground. In summary, tabs 100 can serve to provide either a pole antenna 16B or slot antenna 16A depending on the package 200 and its characteristics.

FIGS. 3A, 3B and 3C illustrate transponder 10 shown in FIG. 2 in more detail. FIG. 3A illustrates transponder 10 from a top view perspective. Tabs 100 are made out of a conductive material. For example, tabs 100 may be constructed out of metals, such as aluminum or copper. FIG. 3B illustrates transponder 100 from a side view perspective. Tabs 100 can either be attached directly to surface 202 or coupled to surface 202 by placing tabs 100 on an optional dielectric adhesive material 102 that is attached to surface 202. Use of adhesive material 102 may be necessary to attach the transponder 10 to surface 202. If transponder 10 is attached on a package 200 constructed out of a conductive material without a slot 300, such that tabs 100 act as a dipole antenna 16B, a dielectric material 102 may be attached between the surface 202 and tabs 100 so that the radiation pattern of the dipole antenna 16B is not affected by the conductive package 200. If such a dielectric material 102 is used, tabs 100 are reactively coupled, rather than directly connected, to surface 202. One tab 100, instead of two tabs 100, may also be used to serve as antenna 16, creating a monopole type radiation pattern. If transponder 10, with tabs 100, is attached across a slot 300 in a conductive surface 202, a slot antenna 16A is formed for antenna 16.

A transponder 10 may be attached to a slot antenna 16A as part of its construction, instead of using a slot 300 created in package 200 to form a slot antenna 16A. FIG. 3C illustrates slot 300 as a rectangular, conductive material 250 having a hollow portion cut out to form an inner, non-conductive portion 252. Tabs 100 are attached to non-conductive portion 252. Slot 300 may be constructed in any shape desired so long as slot 300 is constructed out of a conductive material 250 that contains an inner, non-conductive portion 252. This inner, non-conductive portion 252 can be air, formed by a cut out as illustrated in FIG. 3C, or can be formed by placing a non-conductive material, such as plastic, onto or inside conductive material 250. The conductive material 250 may also contain an adhesive 102, so that slot 300, with transponder 10 attached, can be easily attached to package 200. It may be desirable to provide slot 300 as part of transponder 10, instead of package 200, insofar as this eliminates the requirement to create a slot 300 in package 200 as part of the construction of package 200. For example, it may be impractical or impossible to provide a slot 300 in package 200, but still desirable to attach transponder 10 to package 200 using a slot antenna 16A. As an additional advantage of this embodiment illustrated in FIG. 3C, since slot 300 is provided as part of transponder 10, package 200 can be constructed out of non-conductive material.

FIG. 4 illustrates transponder 10 with tabs 100 acting as both a pole antenna 16B and slot antenna 16A. A slot 300 is provided by cutting out a portion of conductive surface 202. The length of the tabs 100 define the operating frequency of the antenna 16 if tabs 100 are configured to act as a pole antenna 16B. In one embodiment, the tabs 100 are each l/4 in length, or 30.6 millimeters each, to form a dipole antenna 16B with a total length of l/2 and an operating frequency of 2.45 GHz.

As previously discussed, tabs 100 may also serve to form a slot antenna 16A if attached across a slot 300 in a conductive surface 202. The slot 300 length defines the operating frequency of the slot antenna 16A. In one embodiment, the slot 300 length is l/2 or 164 millimeters so that the transponder 10 operates at a frequency of 915 MHz. More information on slot antennas 16A and their operation is described in U.S. Pat. No. 4,975,711, entitled “Slot antenna device for portable radiophone,” incorporated herein by reference in its entirety.

In this manner, the transponder 10 has two antenna 16 configurations that are capable of communicating at two frequencies. If transponder 10 is capable of communicating at two different frequencies, as discussed above, the pole antenna 16B and slot antenna 16A can be configured to communicate at different frequencies as well, enabling the transponder 10 to effectively communicative at both frequencies. This arrangement provides an advantage in particular if 915 MHz is a desired frequency. 915 MHz is frequently used as an operating frequency for electronic communication in the United States, but 2.45 GHz is frequently used outside the United States. Therefore, providing transponder 10 with the capability of communicating at both 915 MHz and 2.45 GHz is advantageous so that transponder 10 can be used for applications in both the United States and abroad. However, if this dual capability is not required, transponder 10 can be configured to operate solely using a pole antenna 16B or slot antenna 16A.

FIGS. 5A and 5B illustrate transponder 10 attached across slots 300 of varying widths. The width of slot 300 affects the impedance of slot 300. For example, a wider slot 300, illustrated in FIG. 5A, may have a higher impedance than the narrower slot 300, illustrated in FIG. 5B. Varying the slot 300 width varies the impedance of the slot antenna 16B to maximize antenna 16 strength. It is desirable to match the impedance of slot 300 to the impedance of transponder 10. In the one embodiment, the slot antenna 16A has a fairly low impedance. Therefore, it is desirable to transform the slot 300 impedance so as to match the impedance of transponder 10, thereby maximizing energy transfer between transponder 10 and slot 300 and maximizing the strength of the radiation pattern emitted by the slot antenna 16A. Matching the impedances also minimizes reflection in the radiation pattern of slot antenna 16A. Transponder 10 may comprise more than one layer, including conductive, dielectric and magnetic materials, such as ferrites, to introduce inductance, thereby aiding modification of the characteristics of surface 202 for impedance matching purposes.

In addition to the composition of transponder 10, the area of tabs 100 affect the impedance of transponder 10. As discussed above, it is desirable to match the impedance of transponder 10 and slot 300. Tabs 100 can also be varied to ensure optimal coupling to surface 202. The impedance of slot 300 may be varied for matching purposes by modifying relevant characteristics of surface 202. For example, a conductive package for food (e.g. foil) may have a surface 202 that is variable in width, dielectric or metallic characteristics. Capacitance of tabs 100 may be taken into consideration for impedance matching when attaching tabs 100 to a particular surface 202. The capacitance of tabs 100 affects the impedance of transponder 10. The total volume of tabs 100 (surface area times thickness) affects their capacitance. Tabs 100 are similar to parallel plate capacitors in series with wireless communication device 10. The larger the volume of tabs 100, the larger their capacitance. It is therefore desirable to design and construct tabs 100 with a capacitance that is commensurate with surface 202 to match impedance of transponder 10 and slot 300 for optimal performance.

An impedance matching network may also be used to match slot 300 impedance to transponder 10 impedance, as discussed in patent application Ser. No. 09/536,334, entitled “Remote Communication Using Slot Antenna,” assigned to assignee of the present invention, and incorporated herein by reference in its entirety.

FIG. 6 illustrates two slots 300A, 300B in surface 202 that are substantially perpendicular to each other, with tabs 100 attached across the slots 300A and 300B. The tabs 100 are attached to slots 300A, 300B at vertical angles, but tabs 100 can also attach to slots 300A, 300B adjacent to each other. This structure creates a circularly polarized slot antenna 16A. Tabs 100 are attached to each of slots 300A and 300B. The length of the first slot 300A, a, is slightly shorter than l/2. The length of the second slot 300B, b, is slightly greater than l/2. The two slots 300A, 300B provide antennas 16 that can be considered resonant circuits, with their associated phase delay at the operating frequency of ±45 degrees to each other. This causes transponder 10 to receive efficiently radiation in more than one dimension and, specifically, in the form of a circular pattern so that the orientation of transponder 10 on surface 202 is somewhat irrelevant for communication.

FIG. 7 illustrates another type of package 200 containing transponder 10. Package 200 is configured to contain gum sucks (not shown). The package 200 is constructed out of a conductive material. Gum sticks are wrapped in their own individual foil wrappers and are placed inside paper non-conductive wrappings 900 contained inside package 200. Parts of the non-conductive wrappings 900 touch or couple to the interior of package 200. Such attaching or coupling provides a slot antenna 300 as previously discussed, where the non-conductive wrappings provide slot 300 and the package 200 inside provides the surrounding conductive material. FIG. 7 illustrates transponder 10 placed inside package 200. Tabs 100 are attached to slot 300, as previously described, to provide communication. Again, tabs 100 are also capable of operating as a pole antenna 16A. The package 200 could also be a cigarette package 200. Again, the tabs 100 may be attached to a slot 300, formed by conductive material of the package 200 surrounding to an internal non-conductive portion internal to package 200, to form slot antenna 16A. In a variation on this embodiment, the slot 300 may be the dielectric that forms the tear away strip that allows such packages to be opened.

FIGS. 8A and 8B illustrate particular manners in which transponder 10 is placed inside package 200. FIG. 8A illustrates transponder 10 located inside the top of package 200 where package 200 opens and seals in a pouch-like fashion. Transponder 10 and tabs 100 are placed inside the top 300. The inside surface 202 of package 200 is a conductive material, such as a foil, including the sides of package 200 that come together when package 200 is closed and sealed. As discussed previously, it is desirable to configure transponder 10 to communicate using a slot antenna 16A when transponder 10 is inside a package 200 constructed out of conductive material. In this embodiment, slot antenna 16A is not formed by cutting out a portion of surface 202, but rather by inserting a non-conductive material 302, such as a dielectric, inside package 200 at the top to form a seal 306 where the sides come together. In this manner, a slot 300 is formed by the separation of the conductive material of inner surface 202 when the sides of package 200, are closed and sealed. Such a method of placing a transponder 10 inside a package 200 may be advantageous where it is desired to protect transponder 10 from theft, tampering or other unwanted elements.

Placing transponder 10 inside package 200 may also be useful to indicate if package 200 has been opened, and, therefore, possibly contaminated. Packages 200 that contain food for consumption or medical devices and equipment requiring sterility are also possible applications. Transponder 10 is placed inside package 200 as previously discussed and illustrated in FIGS. 8A and 8B.

One embodiment to detect the opening of package 200 is to provide tabs 100 constructed out of a material that reacts to ambient air. When package 200 is opened, tabs 100 become exposed to the outside air. If tabs 100 are constructed out of a material that loses its conductivity when exposed to air, transponder 10 cannot be interrogated and/or communicate as effectively since tabs 100 are attached to slot 300 to provide a slot antenna 16A for communication. Thus, lack of communication or degraded communication can be used as an indicator that package 200 has been previously opened.

FIG. 8B illustrates an embodiment where it is not only desirable to place transponder 10 inside package 200, but also to separate transponder 10 from the contents of package 200. In this embodiment, a second seal 304 is provided in package 200. The transponder 10 is located in first seal 306 as previously described above. The transponder 10 is still exposed to air when package 200 is opened, but transponder 10 is not contained in the same portion of package 200 where the contents of package 200 are contained. This embodiment may be desirable when the contents of package 200 are food or liquid for consumption, or other materials where it is not safe or desirable for transponder 10 to come in contact with the contents of package 200.

Another embodiment uses sensor 20 to determine when package 200 is opened. Sensor 20 may be any type of sensor that senses elements of air in the area on the outside of package 200. Air contains oxygen, nitrogen and other gaseous elements. For instance, sensor 20 may be an oxygen sensor, including the sensor described in U.S. Pat. No. 6,027,622, entitled “Sensor element,” incorporated herein by reference in its entirety. Further, sensor 20 can be any type of sensor that senses an environmental factor, such as a gaseous element, that is not contained inside package 200 when sealed with transponder 10 therein.

FIG. 9 illustrates a flow chart of one embodiment of transponder 10 using sensor 20 to determine if package 200 has been opened. The process starts (block 400) and control system 12 receives signals from sensor 20 indicating a reading (block 402). The control system 12 determines if reading from sensor 20 indicates that package 200 is opened (decision 404). If package 200 is opened, control system 102 stores this event in memory 18 to communicate it the next time transponder 10 is interrogated by interrogation reader 50 (block 406). If transponder 10 has transmission capability, transponder 10 may transmit the event of package 200 being open immediately. The process then ends (block 408). Alternatively, if it is determined that the package 200 is not open (decision 404), transponder 10 takes another reading from sensor (block 402), repeating the process again.

FIG. 10 illustrates an embodiment of providing transponders 10 for stamping onto packages 200 in an assembly line or other manufacturing capacity. A carrier 700 is provided that contains individual slides 702. Carrier 700 may be a film or other similar type of material. Transponder 10 is manufactured and placed on carrier 700 during assembly whereby each portion 702 contains one transponder 10. The carrier 700 is constructed out of a conductive material. Carrier 700 may also contain, as part of its construction, one or more conductive tabs 100. Since carrier 700 is a conductive material, tabs 100 are conductive. Transponder 10 is placed onto carrier during assembly and connected to tabs 100 formed in carrier 700. Later during the manufacture or assembly process, transponder 10 is placed onto packages 200. Carrier 700 may have perforations 704 for movement by a machine in an assembly line when mounting transponders 10 to portions 702. Transponder 10, attached to one or more tabs 100 formed in carrier 700, is stamped onto packages 200 in an assembly line by placing carrier 700 proximate to packages 200. The carrier 700 is stamped in such a manner that transponder 10, with tabs 100 attached, is placed onto packages 200. When desired, a stamping process places carrier 700 and a particular portion 702 in contact with package 200 so that transponder 10 is more easily attached to package 200. The package 200 may contain slot 300, whereby transponder 10 is stamped across the slot 300. Transponder 10, tabs 100, or both, may also contain an adhesive 102, as previously discussed, so that transponder 10 attaches to package 200 securely.

FIG. 11A illustrates a top view of transponder 10 having an asymmetrical dipole antenna 16. An asymmetrical dipole antenna 16 is an antenna having a first pole different in shape, including, but not necessarily limited to length, width, volume, and/or density, from the second pole. In FIG. 11A, transponder 10 is coupled to two conductive tabs 100A, 100B. The first conductive tab 100A is asymmetrical with respect to the second conductive tab 10B. The two symmetrical tabs 100A, 100B comprises asymmetrical dipole antenna 16.

FIG. 11B illustrates a side view of one embodiment of the transponder 10 illustrated in FIG. 11A. Tabs 100A, 100B are placed on a dielectric 102. Dielectric 102 acts as an insulator between tabs 100A, 100B and substrate 202. Dielectric 102 is a material that is substantially non-conductive. Examples of materials that may be used to form a dielectric 102 include, but are not limited to: cardboard, plastic, Lexan plastic, fabric, and polypropylene.

If substrate 202 is constructed out of a conductive material, a separate dielectric 102 is provided between substrate 202 and transponder 10 as illustrated in FIG. 11B. If substrate 202 is constructed out of a non-conductive material, substrate 202 may additionally act as dielectric 102. In this case, a ground plane (not shown) may be placed on the opposite side of substrate 202, so that substrate 202, acting as a dielectric 102, is in between transponder 10 and the ground plane. Note that the ground plane may be placed on other places on substrate 202 and not necessarily on the opposite side from transponder 10.

The shape, type, and characteristics of antenna 16 affect the impedance of transponder 10. The substrate 202 also affects the impedance presented to transponder 10 by antenna 16. This is especially true when a thin dielectric 102 is used, because there is less insulation between the transponder 10/antenna 16 and substrate 202. A thin dielectric 102 is between approximately 0.1 mm and 2.0 mm. For transponder 10 to transfer radiation energy from antenna 16 at the highest radiation level possible without losses, the impedance of the transponder 10 should be matched to the impedance of antenna 16 as placed onto substrate 202. For example, in one embodiment, the transponder 10 may have an impedance of 15–j60 ohms. To get optimum transfer of energy between antenna 16 and transponder 10, antenna 16, as placed onto substrate 202, would need to have a conjugate impedance of transponder 10. In practice, impedance matching between transponder 10 and antenna 16 does not have to be exact to have energy transfer between transponder 10 and antenna 16 necessary for communication. Impedances between transponder 10 and antenna 16 that are substantially the same will still allow good energy transfer between antenna 16 and transponder 10.

The transponder 10 may be used with a variety of different substrates 202. To minimize the protrusion of transponder 10 from substrate 202, a thin dielectric 102 is used. Empirical and modeling data have shown that the operation of an asymmetric antenna 16 is substantially insensitive to the size and/or dimensions of substrate 202 when using a dielectric 102 that is relatively thin. Materials with poorly defined structures and/or dielectric constants, such as cardboard, can be used as dielectric 102 materials, which also serve as substrate 202. This discovery allows antenna 16 and transponder 10 impedance to be matched more easily during manufacture without having to take characteristics of substrate 202 into consideration, such as substrate 202 size, thickness, and/or dielectric constant. Substrate 202 does have a certain dielectric constant depending on its material of manufacture and the amount of air present in substrate 202. The dielectric constant is the amount of permissively of a particular material. In addition, antenna 16 elements, such as tabs 100, do not need precise dimensional control, allowing less precise and less expensive materials and methods to be used to define such elements. For example, tabs 100 may be constructed using label printing techniques and conductive ink, such as described in U.S. Pat. No. 5,566,441, entitled “Attaching an electronic circuit to a substrate,” incorporated herein by reference in its entirety.

In the embodiment illustrated in FIGS. 11A and 11B, asymmetrical tabs 100A, 100B act as the asymmetrical antenna 16. Although the impedance of tabs 100A, 100B are substantially insensitive to substrate 202, tabs 100A, 100B may be increased or decreased in size, length, and/or width depending on variations in the thickness and dielectric constant of substrate 202 to provide optimal impedance matching to transponder 10.

FIG. 12A illustrates one modeled example of asymmetrical tabs 100A, 100B used on a substrate 202. Substrate 202 is a common printed circuit board (PCB) material FR4 with an approximate dielectric constant of 4.65. Two additional tabs 101A, 101B are added to tabs 100A, 100B respectively to allow proper modeling and have no effect on results of the asymmetrical antenna 16. FIG. 12B illustrates the predicted gain of antenna 16, which is −0.85 dBi at 915 MHz. FIG. 12C illustrates the modeled gain of an asymmetrical antenna 16, using tabs 100A, 100B, on a substrate 202 having the same dielectric constant as FR4 without losses. The predicted gain for this model is 5.3 dBi at 915 MHz.

As previously stated, tabs 100A, 100B may vary in size in different manners to provide an asymmetrical antenna 16. FIGS. 13, 14A and 14B illustrate other embodiments of asymmetrical antennas 16. FIG. 13 illustrates an embodiment of an asymmetrical antenna 16, whereby tabs 100A, 100B are at right angles to each other. One tab 100A is substantially thinner than the other tab 100B. The performance of the asymmetrical antenna 16 illustrated in FIG. 13 was found to have similar performance characteristics of the asymmetrical antenna 16 illustrated in FIG. 12A.

FIGS. 14A and 14B illustrate two other embodiments of an asymmetrical antenna 16. In FIG. 14A, one tab 100B, hereto represented as being thicker than tab 100A, is in the shape of a ring, and the other tab 100A is nested inside the area bounded by tab 10B. This asymmetrical antenna 16 is almost one-half the total length of the asymmetrical antenna 16 illustrated in FIG. 12A, and may be used in applications where a shorter asymmetrical antenna 16 is desired. Similarly, FIG. 14B depicts another alternate embodiment of asymmetrical antenna 16. In contrast to the embodiment of FIG. 14A, a relatively thick tab 100B is nested within tab 100A, which is arranged in the shape of a ring or loop. Again, asymmetrical antenna 16 in FIG. 14B, is almost one-half the total length of the asymmetrical antenna 16 illustrated in FIG. 12A, and may be used in applications where a shorter asymmetrical antenna 16 is desired. For example, a shorter asymmetrical antenna 16 may be advantageous for design or manufacturing reasons.

FIG. 15A illustrates another embodiment of an asymmetrical antenna dipole antenna 16, whereby substrate 202 is an aluminum can 600. A separate dielectric 102 is provided between transponder 10 having tabs 100A, 100B and can 600, because can 600 is constructed out of a conductive material namely aluminum (as previously discussed). In this particular embodiment, an asymmetrical antenna 16 is created by using tab 100B that is longer in length than tab 100A. FIG. 15B illustrates another asymmetrical antenna embodiment, again using a can 600 as substrate 202. Transponder 10 is placed on the underneath dome 602 of can 600. Two asymmetrical tabs 100A, 100B are provided to form a dipole antenna 16. The resultant dipole antenna 16 is asymmetrical. Tab 100A is shorter in length than tab 10B, and tab 100B is wider than tab 100A.

FIG. 16 illustrates another embodiment of an asymmetrical dipole antenna 16. In this embodiment, transponder 10 is placed into an indentation 500 of substrate 202 so that transponder 10 will not protrude from substrate 202. Transponder 10 may be damaged or hit by an outside force if it protrudes from substrate 202. Tabs 100A, 100B are provided on the surface of substrate 202 on each side of indentation 500. Conductive leads 502 are placed on the inside of indentation 500 and are electrically coupled to tabs 100A, 100B. Such coupling may be accomplished by direct connection, capacitive coupling or inductive coupling. Tabs 100A, 100B are asymmetrical to one another. Transponder 10 has feed lines 504 on each side that couple to conductive leads 502 to couple transponder 10 and tabs 100A, 100B together. In this manner, transponder 10 uses tabs 100A, 100B to form an asymmetrical dipole antenna 16. As illustrated, transponder 10 has not yet been positioned inside indentation 500 below the surface level of substrate 202. When properly positioned, transponder 10 does not protrude from the surface of substrate 202.

FIG. 17 illustrates another embodiment of an asymmetrical antenna 16. In this embodiment, the asymmetrical antenna 16 is provided using a slot 300 to form an asymmetrical slot antenna 16. In this particular embodiment, slot 300 length is λ/4 and slot 300 width is 3.625 mm, although other lengths and widths may be used. Transponder 10 is placed across the slot 300 using tabs 100 to form a slot antenna 16. The asymmetrical nature of the slot antenna 16 is controlled by the location of the placement of tabs 100 across slot 300, and not by differences in the size, width, and/or density of tabs 100. Tabs 100 are placed off-center of slot 300, thereby forming an asymmetrical slot 300. An asymmetrical slot 300 is a slot that is split into at least two separate portions whereby each portion is of different size, width, and/or depth. If substrate 202 is constructed out of a conductive material, a separate dielectric 102 is provided between transponder 10 and substrate 202. If substrate 202 is constructed out of a non-conductive material, substrate 202 is dielectric 102 with a ground plane provided (not shown). Again, this asymmetrical antenna 16 is substantially insensitive to substrate 202 when using a thin dielectric 102, as previously discussed above.

An alternative embodiment to FIG. 17 is to only couple one tab 100 to transponder 10 to provide a monopole asymmetric antenna 16. Again, tab 100 is placed off-center across slot 300. A ground plane is provided and coupled to transponder 10 so as to ground transponder 10.

The focus of the present invention is on the provision of quarter wavelength resonators in a number of different embodiments so as to provide designers of wireless communication devices more options to meet design and performance requirements. For the purposes of the present claims and the following discussion, some of the terms previously used may be used in a slightly different context.

Turning now to FIG. 18, a wireless communication device 1000 is illustrated. Wireless communication device 1000 may comprise a substrate 1002, a ground plane 1004, a wireless communication chip 1006, a feed line 1008, a chip grounding line 1010, an antenna 1012, and an antenna grounding element 1014.

In particular, wireless communication device 1000 may be either active or passive as described with reference to U.S. Pat. No. 5,347,280 (previously incorporated) and U.S. Pat. No. 5,585,953, the latter of which is expressly incorporated by reference. Substrate 1002 may be almost any time of dielectric material, although polypropylene or comparable plastics are specifically contemplated.

Ground plane 1004 may be a foil tape, a conductive material secured to substrate 1002 through other means, or other conductive surface as previously described. Ground plane 1004 may cover substantially all of the rear or bottom surface of substrate 1002. While in this embodiment, the ground plane 1004 is parallel to the antenna 1012 opposite the antenna 1012, other embodiments below show the ground plane 1004 in the same plane as the antenna 1012 and it is also possible to position the antenna 1012 perpendicular to the ground plane 1004.

Wireless communication chip 1006 may comprise a device from INTERMEC as used in their Intellitag® labels and those devices from SCS as used in their DL100 label although other devices are certainly possible, especially in light of the present invention's suitability to both active and passive wireless communication devices 1000. Wireless communication chip 1006 may comprise a control system 12, memory 18, a battery, a sensor 20, and other conventional components, as illustrated in FIG. 1.

Feed line 1008 may be a conductive strip with a non-conductive adhesive or material securing it to substrate 1002 and antenna 1012. The non-conductive material or adhesive allows feed line 1008 to couple capacitively to antenna 1012 without creating a short at frequencies at or near DC. Some wireless communication chips 1006 do not operate with shorts at these low frequencies, hence the need for the insulation. If chip 1006 does work with a low frequency short, the insulation of the adhesive or material may be foregone if needed or desired. The placement, width, and length of feed line 1008 controls the impedance matching between wireless communication chip 1006 and antenna 1012. This structure, and the others presented herein provide an acceptably wide bandwidth functionality in a relatively thin and small structure in close proximity to the ground plane of the structure. Alternative coupling elements instead of feed line 1008 may also be used. These may be added components such as a surface mounted capacitor or the like as needed or desired.

Chip grounding line 1010 electrically connects wireless communication chip 1006 to ground plane 1004 and may be made from any appropriate conductive material.

Antenna 1012 may be formed from any conductive material, such as a foil tape, or printed, such as through the previously described conductive ink or the like as needed or desired. First end 1016 is an open circuit, while second end 1018 is short circuited to ground plane 1004 by antenna grounding element 1014. It is further possible in this, and the other embodiments presented herein to indirectly connect the second end 1018 to the ground plane 1004 by inductive or capacitive coupling. Note that it is possible in the capacitive coupling embodiment just mentioned to position a separate wireless communication chip 1006 (not shown) with a non-conducting glue as the connector between the antenna 1012 and the ground plane 1004. This may simplify the assembly process in certain assembly techniques. It should be appreciated that almost every element will have some small impedance and the term “electrically shorted” as used herein includes such low impedance resistive or reactive elements. While antenna grounding element 1014 is illustrated as a conductive strip wrapping around the edge, alternative shorting methods are also contemplated, such as copper plated through holes, commonly used in printed circuit board (PCB) processes, or a conductive material sucked through a hole.

Antenna 1012 may be a quarter wavelength long for the desired operating frequency. This distance is measured from first end 1016 to second end 1018. The actual length will vary on a number of factors, such as the effective length of the antenna grounding element 1014 around the edge of the substrate 1002, thickness of the substrate 1002, width of the resonant element, dielectric constant of the substrate 1002, thickness of the substrate 1002, desired impedance at the coupling point, and other factors understood in the art.

In this embodiment, wireless communication chip 1006 is generally perpendicular to the primary axis of antenna 1012.

In contrast, as illustrated in FIG. 19, the elements of wireless communication device 1000A remain essentially unchanged, however, the position of wireless communication chip 1006 has changed so that now chip 1006 is substantially parallel to antenna 1012. Also note that chip grounding line 1010 has been extended and feed line 1008 couples to chip grounding line 1010 instead of the pins of chip 1006 as illustrated in wireless communication device 1000.

The main advantage of this approach is that the structure may be simpler to produce, with feed line 1008 fabricated as a separate label added during production.

A third embodiment, wireless communication device 1000B, is illustrated in FIG. 20, wherein quarter wavelength antenna 1012 is formed by a length of CoPlanar Waveguide Ground plane (CPWG) 1020 positioned on the same surface of substrate 1002 as antenna 1012. First end 1016 is still an open circuit, and second end 1018 is still shorted electrically to ground. Gap 1022 separates antenna 1012 from CPWG 1020.

In CPWG technology, the fields associated with the RF signal are contained between a central strip (antenna 1012) and two planar areas of ground plane (1020). A rear ground plane (not shown) underneath the dielectric is not required but can be accommodated. An advantage of this embodiment is that a connection from the top surface to the back surface is no longer required, simplifying construction. Alternatively, different impedance matching characteristics may be possible with this arrangement or certain design parameters may be enabled with this arrangement

Instead of feed line 1008 coupling wireless communication chip 1006 to antenna 1012, an inter digital capacitive structure may be used as illustrated in FIGS. 21 and 22. Inter digital capacitive structures include those that have a stub similar to a finger (digital) that extends into the general space of another element (inter). The structures capacitively couple to one another. A further discussion of inter digital structures may be found in IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES A PUBLICATION OF THE IEEE MICROWAVE THEORY AND TECHNIQUES SOCIETY March 2000, Volume 48, Number 03 ACCURATE CIRCUIT MODEL OF INTERDIGITAL CAPACITOR AND ITS APPLICATION TO DESIGN OF NEW QUASI-LUMPED MINIATURIZED FILTERS WITH SUPPRESSION OF HARMONIC RESONANCE by L. Zhu and K. Wu.

In particular, FIG. 21 illustrates a wireless communication device 1000C comprising a wireless communication chip 1006 mounted on substrate 1002 and grounded via chip grounding line 1010. Antenna 1012 is likewise grounded via antenna grounding element 1014. In place of feed line 1008, a stub 1024 extends into the area of antenna 1012. Gap 1026 allows stub 1024 to couple capacitively to antenna 1012.

FIG. 22, in contrast, discloses a wireless communication device 1000D comprising a plurality of stubs 1028 that extend into the area of antenna 1012. The gap, size and number of inter stubs 1024 or 1028 determines the relative capacitive cross coupling between stubs 1024, 1028 and antenna 1012. The more circumferential length in close proximity increases the capacitance. The narrower the gap between the elements increases the capacitance. The size of the stubs may affect at which frequencies the capacitance is maximized. As long as the elements are short in comparison to a wavelength at the operating frequency the inter digital area's electrical characteristics are primarily those of a capacitor.

It should be appreciated that both of these techniques may be used with any of the techniques described with respect to FIGS. 18-20.

This method of proving a non-contacting feed line 1008 or stubs 1024 or 1028 has some interesting variants that can give multi-frequency operation for a wireless communication device 1000. For example, consider wireless communication device 100OF disclosed in FIG. 23.

In particular, wireless communication device 1000F comprises a substrate 1002 with a rear ground plane 1004. Wireless communication chip 1006 is connected to ground plane 1004 by a chip grounding line 1010. Antenna 1012A acts (with ground plane 1004) as a half-wavelength patch antenna at a first operating frequency, such as 915 MHz. The operating frequency and dielectric constant of substrate 1002 determine the dimensions of the square patch.

A short section of CPWG transmission feed line 1008A feeds patch antenna 1012A capacitively at the first frequency but acts as an antenna at a second frequency, allowing the device to work efficiently at both frequencies. If increased capacitance for the feed is required a inter digital structure with more fingers can be used either along the entire length of the feed line or at its end. In an exemplary embodiment, the antenna 1012A is approximately 53 mm to a side allowing operation at 915 MHz, and the transmission feed line 1008A is approximately 16 mm long allowing operation at 2.45 GHz. Patch antennas are well understood in the antenna art, and are popular for low profile applications. They commonly consist of a rectangular metal patch on a dielectric-coated ground plane. For a further discussion of patch antennas, reference is made to U.S. Pat. No. 6,140,969, which is hereby incorporated by reference.

This structure can also potentially be used with a l/4 resonant element, as shown in the earlier diagrams. An example of this ability is illustrated in FIG. 24. In this embodiment, in wireless communication device 1000G, substrate 1002, ground plane 1004, and wireless communication chip 1006 remain essentially unchanged as are chip grounding line 1010 and antenna grounding element 1014. Feed line 1008B acts as a feeding element at UHF, but acts as an antenna at microwave frequencies. Antenna 1012B acts as an antenna at UHF frequencies and has an open circuit at first end 1016.

Construction of one embodiment of these antenna arrangements is illustrated in FIGS. 25–28. A kit 1050, illustrated in FIG. 25, for assembling an quarter wavelength antenna comprises a substrate 1002, a chip component 1052, and a ground plane/antenna component 1054. Substrate 1002 may be of any suitable dielectric material. Chip component 1052 comprises a conductive strip comprising antenna feed line 1008 and chip grounding line 1010 coupled to wireless communication chip 1006. As previously noted, there may be a non-conductive adhesive or material disposed on antenna feed line 1008.

Groundplane/antenna component 1054 comprises a conductive material with ground plane 1004 and antenna 1012, coupled by antenna grounding element 1014.

As illustrated in FIG. 26, ground plane/antenna component 1054 is wrapped around substrate 1002 with groundplane 1004 substantially covering a rear surface of substrate 1002 and antenna 1012 being disposed on the opposite surface. A suitable adhesive may secure component 1054 to substrate 1002.

Having wrapped ground plane/antenna component 1054 around substrate 1002, chip component 1052 is then wrapped around the side of substrate 1002. Antenna feed line 1008 may be coupled to antenna 1012 and chip grounding line 1010 coupling chip 1006 to ground plane 1004.

This assembly routine results in an assembled wireless communication device 1000 as illustrated in FIG. 28. Exemplary dimensions for the components are as follows. For substrate 1002, 63 mm long×25 mm wide, with the thickness determined by the desired operating frequencies. For chip component 1052, a feed line 1008 approximately 10 mm long and a ground line 1010 approximately 20 mm long. For ground plane/antenna component 1054, an antenna 1012 and ground element 1014 approximately 53.5 mm long and having a width of 10 mm. Ground plane 1004 may be 63 mm long by 25 mm wide. These dimensions provide operation at one desired frequency, and it should be appreciated that other operating frequencies may require different dimensions. They are not intended to be limiting, but rather exemplary of one embodiment of the present invention.

Certain modifications and improvements will occur to those skilled in the art upon a reading of the foregoing description. It should be understood that the present invention is not limited to any particular type of wireless communication device, tabs, packaging, or slot arrangement. For the purposes of this application, couple, coupled, or coupling is defined as either directly connecting or reactive coupling. Reactive coupling is defined as either capacitive or inductive coupling.

One of ordinary skill in the art will recognize that there are different manners in which these elements can provide to accomplish the present invention. The present invention is intended to cover what is claimed and any equivalents. The specific embodiments used herein are to aid in the understanding of the present invention, and should not be used to limit the scope of the invention in a manner narrower than the claims and their equivalents. 

1. A wireless communication device, comprising: a substrate; a wireless communication chip positioned on said substrate; a ground plane positioned on said substrate; and an antenna electrically coupled to said wireless communication chip and electrically shorted at one end to said ground plane.
 2. The wireless communication device of claim 1, wherein said wireless communication chip is positioned on a first side of said substrate and said ground plane is positioned on an opposite side of said substrate.
 3. The wireless communication device of claim 1, wherein said wireless communication chip is electrically coupled to said ground plane.
 4. The wireless communication device of claim 3, wherein said wireless communication chip is directly coupled to said ground plane.
 5. The wireless communication device of claim 3, wherein said wireless communication chip is reactively coupled to said ground plane.
 6. The wireless communication device of claim 1, wherein said wireless communication chip is positioned along an axis substantially perpendicular to a primary axis of said antenna.
 7. The wireless communication device of claim 1, wherein said wireless communication chip is positioned along an axis substantially parallel to a primary axis of said antenna.
 8. The wireless communication device of claim 1, wherein said antenna and said ground plane are connected to an antenna grounding element.
 9. The wireless communication device of claim 1, wherein said ground plane and said antenna are positioned on one side of said substrate.
 10. The wireless communication device of claim 1, wherein said wireless communication chip is capacitively coupled to said antenna.
 11. The wireless communication device of claim 10, wherein said wireless communication chip is capacitively coupled to said antenna by a non-conductive adhesive being interposed between a feed line extending from said wireless communication chip and said antenna.
 12. The wireless communication device of claim 10, wherein said wireless communication chip is capacitively coupled to said antenna by at least one inter digital stub.
 13. The wireless communication device of claim 1, further comprising a second antenna operating at a second frequency distinct from a first antenna's operating frequency of said first antenna.
 14. The wireless communication device of claim 13, wherein said second antenna is a patch antenna.
 15. The wireless communication device of claim 13, wherein said first antenna acts as a feed line to couple capacitively said second antenna to said wireless communication chip.
 16. The wireless communication device of claim 1, wherein said antenna and said ground plane are cut from a unitary piece of conductive foil.
 17. The wireless communication device of claim 1, wherein said substrate comprises a plastic material.
 18. A method of constructing a wireless communication device, comprising: creating an ground plane/antenna component from a unitary piece of conductive foil; creating a chip component comprising a feed line, a chip grounding line, and a wireless communication chip; wrapping said ground plane/antenna component around a substrate such that an antenna portion of said ground plane/antenna component is positioned on a side opposite that where a ground plane portion of said ground plane/antenna component is positioned; and wrapping said chip component around a side of said substrate such that the chip is grounded by the chip grounding line and coupled to said antenna by said feed line.
 19. The method of claim 18, further comprising adhering said ground plane/antenna component to said substrate.
 20. The method of claim 18, further comprising adhering said chip component to said substrate. 